An exemplary embodiment of the present disclosure provides a knee exoskeleton comprising a first interface, a second interface, an actuator, and a controller. The first interface can be configured to interface with a portion of a leg of a user above a knee joint of the user. The second interface can be configured to interface with a portion of the leg of the user below the knee joint of the user. The actuator can be configured to generate a torque to cause a movement of at least one of the first and second interfaces. The controller can be configured to control the actuator to vary the magnitude of torque generated by the actuator.

A probe device provides an enhanced bioelectric and spring-loaded sensing tip with an integrated force sensor. The probe device measures the bioelectric conductance value from a patient for therapeutic and/or diagnostic purpose using the spring-loaded sensing tip. In addition, the probe device measures the force applied by the spring-loaded sensing tip against the patient using the integrated force sensor. Using feedback from the force sensor and the bioconductive data of the patient, the force applied at the spring-loaded sensing tip may be adjusted to obtain improved results.

Provided herein are compression devices and methods of use thereof, and methods of treatment for patients with edema. The compression device can include a sleeve having a plurality of inflatable chambers and at least one pneumatic pump that can be coupled to at least one inflatable chamber. The device can also include a portable bio impedance analyzer, a microcontroller and a battery. The battery can power the microcontroller and the at least one pneumatic pump and the microcontroller can control the both the portable bio impedance analyzer and the at least one pneumatic pump. The device can be used to treat a patient. Body impedance values are received from the sensors. The inflatable chambers are inflated in a sequence and to a pressure level based on the instructions from the microcontroller when the body impedance values meet a first predefined threshold.

Methods and devices that improve focus, concentration, learning capacity, visual memory, new learning, sustained attention, cognition and/or interoception in a human using mechanical affective touch therapy are provided. In one embodiment, the method comprises delivering to a human body transcutaneous mechanical vibrations having a frequency of less than 20 Hz for at least 10 minutes, at least 2 times per day, for a period of at least 4 weeks, thereby providing the human with transcutaneous mechanical stimulation that improves focus, concentration, learning capacity, visual memory, new learning, sustained attention, cognition and interoception in that human.

Systems, computer-implemented methods and/or computer program products that facilitate real-time response to defined symptoms are provided. In one embodiment, a computer-implemented method comprises: monitoring, by a system operatively coupled to a processor, a state of an entity; detecting, by the system, defined symptoms of the entity by analyzing the state of the entity; and transmitting, by the system, a signal that causes audio response or a haptic response to be provided to the entity, wherein transmission of the signal that causes the audio response or the haptic response is based on detection of the defined symptoms.

A method for treating chest wall injuries, including rib fractures, flail chest injuries or surgical incisions. The method comprising creating a localized airtight compartment external to the chest wall and fully covering the area of injury, varying the pressure within the compartment, and providing dynamic real-time counter forces that act reciprocal to the intrathoracic pressure changes that occur during ventilation. In a preferred embodiment, the apparatus has the capability of sensing the patient's chest wall motion created by ventilation, a pressure control component capable of varying the pressure within the airtight compartment such that it opposes pressure changes within the chest. The apparatus would be particularly useful in preventing the paradoxical movement of flail chest injuries. The method would also lessen pain experienced by patients with thoracic injuries such as rib fractures and post operative suffering.

Arrangement for compression sensing between two objects, preferably for compression treatment, in particular compression therapy arrangement, comprising a first object, e. f. a compression garment adapted to exert external pressure on a second object, e. g. a body portion and at least one sensor device associated with the first object and having at least one pressure sensor for determining the external pressure, wherein the pressure sensor comprises at least one pressure circuitry, having a sensing impedance which is dependent on the external pressure and at least one reference circuitry having a reference impedance which is essentially independent from the external pressure, wherein a cumulative signal which is dependent on the external pressure and other external influences acting in the vicinity of the sensing impedance is derivable from the pressure circuitry and a reference signal which is essentially independent from the external pressures but dependent on other external influences acting in the vicinity of the reference circuitry.

Methods and systems are disclosed for capturing sensor data collected by a personal massaging device with associated sensors, analyzing the data, determining biofeedback data based on the sensor data, and according to some embodiments generating a sexual response profile based on the biofeedback data and a model of human sexual response. Data may be collected and analyzed for a number of uses, including but not limited to: (1) studying human sexual response, (2) adjusting outputs of the personal massaging device based on preset conditions, (3) treating sexual dysfunction conditions, and (4) improving sexual experiences.

Systems, computer-implemented methods and/or computer program products that facilitate real-time response to defined symptoms are provided. In one embodiment, a computer-implemented method comprises: monitoring, by a system operatively coupled to a processor, a state of an entity; detecting, by the system, defined symptoms of the entity by analyzing the state of the entity; and transmitting, by the system, a signal that causes audio response or a haptic response to be provided to the entity, wherein transmission of the signal that causes the audio response or the haptic response is based on detection of the defined symptoms.

A patient treatment unit and method analyzes and treats pain in tissues by applying an electrical pulse train to the affected tissue. The impedance of the affected tissue is measured, and the measured impedance is correlated to a level of pain in the patient. The pulse train is further applied in response to the measured impedance to reduce the patient's pain. The patient treatment unit includes a probe stimulus generator that outputs the pulse train. The treatment unit also includes a pair of probes for contacting the patient's body and receiving the pulse train. The pulse has improved shaping based on isolation of high voltage from a low voltage control. The unit further includes a body impedance analysis circuit that senses voltage and current via the probes when the probes are contacting the patient and observe the impedance. A monitor is electrically coupled to the body impedance analysis circuit and provides an indication of the measured impedance indicative of the patient's level of pain in real-time.